linux/drivers/net/ipa/gsi.c

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// SPDX-License-Identifier: GPL-2.0
/* Copyright (c) 2015-2018, The Linux Foundation. All rights reserved.
* Copyright (C) 2018-2023 Linaro Ltd.
*/
#include <linux/types.h>
#include <linux/bits.h>
#include <linux/bitfield.h>
#include <linux/mutex.h>
#include <linux/completion.h>
#include <linux/io.h>
#include <linux/bug.h>
#include <linux/interrupt.h>
#include <linux/platform_device.h>
#include <linux/netdevice.h>
#include "gsi.h"
#include "reg.h"
#include "gsi_reg.h"
#include "gsi_private.h"
#include "gsi_trans.h"
#include "ipa_gsi.h"
#include "ipa_data.h"
#include "ipa_version.h"
/**
* DOC: The IPA Generic Software Interface
*
* The generic software interface (GSI) is an integral component of the IPA,
* providing a well-defined communication layer between the AP subsystem
* and the IPA core. The modem uses the GSI layer as well.
*
* -------- ---------
* | | | |
* | AP +<---. .----+ Modem |
* | +--. | | .->+ |
* | | | | | | | |
* -------- | | | | ---------
* v | v |
* --+-+---+-+--
* | GSI |
* |-----------|
* | |
* | IPA |
* | |
* -------------
*
* In the above diagram, the AP and Modem represent "execution environments"
* (EEs), which are independent operating environments that use the IPA for
* data transfer.
*
* Each EE uses a set of unidirectional GSI "channels," which allow transfer
* of data to or from the IPA. A channel is implemented as a ring buffer,
* with a DRAM-resident array of "transfer elements" (TREs) available to
* describe transfers to or from other EEs through the IPA. A transfer
* element can also contain an immediate command, requesting the IPA perform
* actions other than data transfer.
*
* Each TRE refers to a block of data--also located in DRAM. After writing
* one or more TREs to a channel, the writer (either the IPA or an EE) writes
* a doorbell register to inform the receiving side how many elements have
* been written.
*
* Each channel has a GSI "event ring" associated with it. An event ring
* is implemented very much like a channel ring, but is always directed from
* the IPA to an EE. The IPA notifies an EE (such as the AP) about channel
* events by adding an entry to the event ring associated with the channel.
* The GSI then writes its doorbell for the event ring, causing the target
* EE to be interrupted. Each entry in an event ring contains a pointer
* to the channel TRE whose completion the event represents.
*
* Each TRE in a channel ring has a set of flags. One flag indicates whether
* the completion of the transfer operation generates an entry (and possibly
* an interrupt) in the channel's event ring. Other flags allow transfer
* elements to be chained together, forming a single logical transaction.
* TRE flags are used to control whether and when interrupts are generated
* to signal completion of channel transfers.
*
* Elements in channel and event rings are completed (or consumed) strictly
* in order. Completion of one entry implies the completion of all preceding
* entries. A single completion interrupt can therefore communicate the
* completion of many transfers.
*
* Note that all GSI registers are little-endian, which is the assumed
* endianness of I/O space accesses. The accessor functions perform byte
* swapping if needed (i.e., for a big endian CPU).
*/
/* Delay period for interrupt moderation (in 32KHz IPA internal timer ticks) */
#define GSI_EVT_RING_INT_MODT (32 * 1) /* 1ms under 32KHz clock */
#define GSI_CMD_TIMEOUT 50 /* milliseconds */
#define GSI_CHANNEL_STOP_RETRIES 10
#define GSI_CHANNEL_MODEM_HALT_RETRIES 10
net: ipa: support enhanced channel flow control IPA v4.2 introduced GSI channel flow control, used instead of IPA endpoint DELAY mode to prevent a TX channel from injecting packets into the IPA core. It used a new FLOW_CONTROLLED channel state which could be entered using GSI generic commands. IPA v4.11 extended the channel flow control model. Rather than having a distinct FLOW_CONTROLLED channel state, each channel has a "flow control" property that can be enabled or not--independent of the channel state. The AP (or modem) can modify this property using the same GSI generic commands as before. The AP only uses channel flow control on modem TX channels, and only when recovering from a modem crash. The AP has no way to discover the state of a modem channel, so the fact that (starting with IPA v4.11) flow control no longer uses a distinct channel state is invisible to the AP. So enhanced flow control generally does not change the way AP uses flow control. There are a few small differences, however: - There is a notion of "primary" or "secondary" flow control, and when enabling or disabling flow control that must be specified in a new field in the GSI generic command register. For now, we always specify 0 (meaning "primary"). - When disabling flow control, it's possible a request will need to be retried. We retry up to 5 times in this case. - Another new generic command allows the current flow control state to be queried. We do not use this. Other than the need for retries, the code essentially works the same way as before. Signed-off-by: Alex Elder <elder@linaro.org> Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2021-11-25 03:44:16 +08:00
#define GSI_CHANNEL_MODEM_FLOW_RETRIES 5 /* disable flow control only */
#define GSI_MHI_EVENT_ID_START 10 /* 1st reserved event id */
#define GSI_MHI_EVENT_ID_END 16 /* Last reserved event id */
#define GSI_ISR_MAX_ITER 50 /* Detect interrupt storms */
/* An entry in an event ring */
struct gsi_event {
__le64 xfer_ptr;
__le16 len;
u8 reserved1;
u8 code;
__le16 reserved2;
u8 type;
u8 chid;
};
/** gsi_channel_scratch_gpi - GPI protocol scratch register
* @max_outstanding_tre:
* Defines the maximum number of TREs allowed in a single transaction
* on a channel (in bytes). This determines the amount of prefetch
* performed by the hardware. We configure this to equal the size of
* the TLV FIFO for the channel.
* @outstanding_threshold:
* Defines the threshold (in bytes) determining when the sequencer
* should update the channel doorbell. We configure this to equal
* the size of two TREs.
*/
struct gsi_channel_scratch_gpi {
u64 reserved1;
u16 reserved2;
u16 max_outstanding_tre;
u16 reserved3;
u16 outstanding_threshold;
};
/** gsi_channel_scratch - channel scratch configuration area
*
* The exact interpretation of this register is protocol-specific.
* We only use GPI channels; see struct gsi_channel_scratch_gpi, above.
*/
union gsi_channel_scratch {
struct gsi_channel_scratch_gpi gpi;
struct {
u32 word1;
u32 word2;
u32 word3;
u32 word4;
} data;
};
/* Check things that can be validated at build time. */
static void gsi_validate_build(void)
{
/* This is used as a divisor */
BUILD_BUG_ON(!GSI_RING_ELEMENT_SIZE);
/* Code assumes the size of channel and event ring element are
* the same (and fixed). Make sure the size of an event ring
* element is what's expected.
*/
BUILD_BUG_ON(sizeof(struct gsi_event) != GSI_RING_ELEMENT_SIZE);
/* Hardware requires a 2^n ring size. We ensure the number of
* elements in an event ring is a power of 2 elsewhere; this
* ensure the elements themselves meet the requirement.
*/
BUILD_BUG_ON(!is_power_of_2(GSI_RING_ELEMENT_SIZE));
}
/* Return the channel id associated with a given channel */
static u32 gsi_channel_id(struct gsi_channel *channel)
{
return channel - &channel->gsi->channel[0];
}
/* An initialized channel has a non-null GSI pointer */
static bool gsi_channel_initialized(struct gsi_channel *channel)
{
return !!channel->gsi;
}
/* Encode the channel protocol for the CH_C_CNTXT_0 register */
static u32 ch_c_cntxt_0_type_encode(enum ipa_version version,
const struct reg *reg,
enum gsi_channel_type type)
{
u32 val;
val = reg_encode(reg, CHTYPE_PROTOCOL, type);
if (version < IPA_VERSION_4_5 || version >= IPA_VERSION_5_0)
return val;
type >>= hweight32(reg_fmask(reg, CHTYPE_PROTOCOL));
return val | reg_encode(reg, CHTYPE_PROTOCOL_MSB, type);
}
/* Update the GSI IRQ type register with the cached value */
static void gsi_irq_type_update(struct gsi *gsi, u32 val)
{
const struct reg *reg = gsi_reg(gsi, CNTXT_TYPE_IRQ_MSK);
gsi->type_enabled_bitmap = val;
iowrite32(val, gsi->virt + reg_offset(reg));
}
static void gsi_irq_type_enable(struct gsi *gsi, enum gsi_irq_type_id type_id)
{
gsi_irq_type_update(gsi, gsi->type_enabled_bitmap | type_id);
}
static void gsi_irq_type_disable(struct gsi *gsi, enum gsi_irq_type_id type_id)
{
gsi_irq_type_update(gsi, gsi->type_enabled_bitmap & ~type_id);
}
/* Event ring commands are performed one at a time. Their completion
* is signaled by the event ring control GSI interrupt type, which is
* only enabled when we issue an event ring command. Only the event
* ring being operated on has this interrupt enabled.
*/
static void gsi_irq_ev_ctrl_enable(struct gsi *gsi, u32 evt_ring_id)
{
u32 val = BIT(evt_ring_id);
const struct reg *reg;
/* There's a small chance that a previous command completed
* after the interrupt was disabled, so make sure we have no
* pending interrupts before we enable them.
*/
reg = gsi_reg(gsi, CNTXT_SRC_EV_CH_IRQ_CLR);
iowrite32(~0, gsi->virt + reg_offset(reg));
reg = gsi_reg(gsi, CNTXT_SRC_EV_CH_IRQ_MSK);
iowrite32(val, gsi->virt + reg_offset(reg));
gsi_irq_type_enable(gsi, GSI_EV_CTRL);
}
/* Disable event ring control interrupts */
static void gsi_irq_ev_ctrl_disable(struct gsi *gsi)
{
const struct reg *reg;
gsi_irq_type_disable(gsi, GSI_EV_CTRL);
reg = gsi_reg(gsi, CNTXT_SRC_EV_CH_IRQ_MSK);
iowrite32(0, gsi->virt + reg_offset(reg));
}
/* Channel commands are performed one at a time. Their completion is
* signaled by the channel control GSI interrupt type, which is only
* enabled when we issue a channel command. Only the channel being
* operated on has this interrupt enabled.
*/
static void gsi_irq_ch_ctrl_enable(struct gsi *gsi, u32 channel_id)
{
u32 val = BIT(channel_id);
const struct reg *reg;
/* There's a small chance that a previous command completed
* after the interrupt was disabled, so make sure we have no
* pending interrupts before we enable them.
*/
reg = gsi_reg(gsi, CNTXT_SRC_CH_IRQ_CLR);
iowrite32(~0, gsi->virt + reg_offset(reg));
reg = gsi_reg(gsi, CNTXT_SRC_CH_IRQ_MSK);
iowrite32(val, gsi->virt + reg_offset(reg));
gsi_irq_type_enable(gsi, GSI_CH_CTRL);
}
/* Disable channel control interrupts */
static void gsi_irq_ch_ctrl_disable(struct gsi *gsi)
{
const struct reg *reg;
gsi_irq_type_disable(gsi, GSI_CH_CTRL);
reg = gsi_reg(gsi, CNTXT_SRC_CH_IRQ_MSK);
iowrite32(0, gsi->virt + reg_offset(reg));
}
static void gsi_irq_ieob_enable_one(struct gsi *gsi, u32 evt_ring_id)
{
bool enable_ieob = !gsi->ieob_enabled_bitmap;
const struct reg *reg;
u32 val;
gsi->ieob_enabled_bitmap |= BIT(evt_ring_id);
reg = gsi_reg(gsi, CNTXT_SRC_IEOB_IRQ_MSK);
val = gsi->ieob_enabled_bitmap;
iowrite32(val, gsi->virt + reg_offset(reg));
/* Enable the interrupt type if this is the first channel enabled */
if (enable_ieob)
gsi_irq_type_enable(gsi, GSI_IEOB);
}
static void gsi_irq_ieob_disable(struct gsi *gsi, u32 event_mask)
{
const struct reg *reg;
u32 val;
gsi->ieob_enabled_bitmap &= ~event_mask;
/* Disable the interrupt type if this was the last enabled channel */
if (!gsi->ieob_enabled_bitmap)
gsi_irq_type_disable(gsi, GSI_IEOB);
reg = gsi_reg(gsi, CNTXT_SRC_IEOB_IRQ_MSK);
val = gsi->ieob_enabled_bitmap;
iowrite32(val, gsi->virt + reg_offset(reg));
}
static void gsi_irq_ieob_disable_one(struct gsi *gsi, u32 evt_ring_id)
{
gsi_irq_ieob_disable(gsi, BIT(evt_ring_id));
}
/* Enable all GSI_interrupt types */
static void gsi_irq_enable(struct gsi *gsi)
{
const struct reg *reg;
u32 val;
/* Global interrupts include hardware error reports. Enable
* that so we can at least report the error should it occur.
*/
reg = gsi_reg(gsi, CNTXT_GLOB_IRQ_EN);
iowrite32(ERROR_INT, gsi->virt + reg_offset(reg));
gsi_irq_type_update(gsi, gsi->type_enabled_bitmap | GSI_GLOB_EE);
/* General GSI interrupts are reported to all EEs; if they occur
* they are unrecoverable (without reset). A breakpoint interrupt
* also exists, but we don't support that. We want to be notified
* of errors so we can report them, even if they can't be handled.
*/
reg = gsi_reg(gsi, CNTXT_GSI_IRQ_EN);
val = BUS_ERROR;
val |= CMD_FIFO_OVRFLOW;
val |= MCS_STACK_OVRFLOW;
iowrite32(val, gsi->virt + reg_offset(reg));
gsi_irq_type_update(gsi, gsi->type_enabled_bitmap | GSI_GENERAL);
}
/* Disable all GSI interrupt types */
static void gsi_irq_disable(struct gsi *gsi)
{
const struct reg *reg;
gsi_irq_type_update(gsi, 0);
/* Clear the type-specific interrupt masks set by gsi_irq_enable() */
reg = gsi_reg(gsi, CNTXT_GSI_IRQ_EN);
iowrite32(0, gsi->virt + reg_offset(reg));
reg = gsi_reg(gsi, CNTXT_GLOB_IRQ_EN);
iowrite32(0, gsi->virt + reg_offset(reg));
}
/* Return the virtual address associated with a ring index */
void *gsi_ring_virt(struct gsi_ring *ring, u32 index)
{
/* Note: index *must* be used modulo the ring count here */
return ring->virt + (index % ring->count) * GSI_RING_ELEMENT_SIZE;
}
/* Return the 32-bit DMA address associated with a ring index */
static u32 gsi_ring_addr(struct gsi_ring *ring, u32 index)
{
return lower_32_bits(ring->addr) + index * GSI_RING_ELEMENT_SIZE;
}
/* Return the ring index of a 32-bit ring offset */
static u32 gsi_ring_index(struct gsi_ring *ring, u32 offset)
{
return (offset - gsi_ring_addr(ring, 0)) / GSI_RING_ELEMENT_SIZE;
}
/* Issue a GSI command by writing a value to a register, then wait for
* completion to be signaled. Returns true if the command completes
* or false if it times out.
*/
static bool gsi_command(struct gsi *gsi, u32 reg, u32 val)
{
unsigned long timeout = msecs_to_jiffies(GSI_CMD_TIMEOUT);
struct completion *completion = &gsi->completion;
reinit_completion(completion);
iowrite32(val, gsi->virt + reg);
return !!wait_for_completion_timeout(completion, timeout);
}
/* Return the hardware's notion of the current state of an event ring */
static enum gsi_evt_ring_state
gsi_evt_ring_state(struct gsi *gsi, u32 evt_ring_id)
{
const struct reg *reg = gsi_reg(gsi, EV_CH_E_CNTXT_0);
u32 val;
val = ioread32(gsi->virt + reg_n_offset(reg, evt_ring_id));
return reg_decode(reg, EV_CHSTATE, val);
}
/* Issue an event ring command and wait for it to complete */
static void gsi_evt_ring_command(struct gsi *gsi, u32 evt_ring_id,
enum gsi_evt_cmd_opcode opcode)
{
struct device *dev = gsi->dev;
const struct reg *reg;
bool timeout;
u32 val;
/* Enable the completion interrupt for the command */
gsi_irq_ev_ctrl_enable(gsi, evt_ring_id);
reg = gsi_reg(gsi, EV_CH_CMD);
val = reg_encode(reg, EV_CHID, evt_ring_id);
val |= reg_encode(reg, EV_OPCODE, opcode);
timeout = !gsi_command(gsi, reg_offset(reg), val);
gsi_irq_ev_ctrl_disable(gsi);
if (!timeout)
return;
dev_err(dev, "GSI command %u for event ring %u timed out, state %u\n",
opcode, evt_ring_id, gsi_evt_ring_state(gsi, evt_ring_id));
}
/* Allocate an event ring in NOT_ALLOCATED state */
static int gsi_evt_ring_alloc_command(struct gsi *gsi, u32 evt_ring_id)
{
enum gsi_evt_ring_state state;
/* Get initial event ring state */
state = gsi_evt_ring_state(gsi, evt_ring_id);
if (state != GSI_EVT_RING_STATE_NOT_ALLOCATED) {
dev_err(gsi->dev, "event ring %u bad state %u before alloc\n",
evt_ring_id, state);
return -EINVAL;
}
gsi_evt_ring_command(gsi, evt_ring_id, GSI_EVT_ALLOCATE);
/* If successful the event ring state will have changed */
state = gsi_evt_ring_state(gsi, evt_ring_id);
if (state == GSI_EVT_RING_STATE_ALLOCATED)
return 0;
dev_err(gsi->dev, "event ring %u bad state %u after alloc\n",
evt_ring_id, state);
return -EIO;
}
/* Reset a GSI event ring in ALLOCATED or ERROR state. */
static void gsi_evt_ring_reset_command(struct gsi *gsi, u32 evt_ring_id)
{
enum gsi_evt_ring_state state;
state = gsi_evt_ring_state(gsi, evt_ring_id);
if (state != GSI_EVT_RING_STATE_ALLOCATED &&
state != GSI_EVT_RING_STATE_ERROR) {
dev_err(gsi->dev, "event ring %u bad state %u before reset\n",
evt_ring_id, state);
return;
}
gsi_evt_ring_command(gsi, evt_ring_id, GSI_EVT_RESET);
/* If successful the event ring state will have changed */
state = gsi_evt_ring_state(gsi, evt_ring_id);
if (state == GSI_EVT_RING_STATE_ALLOCATED)
return;
dev_err(gsi->dev, "event ring %u bad state %u after reset\n",
evt_ring_id, state);
}
/* Issue a hardware de-allocation request for an allocated event ring */
static void gsi_evt_ring_de_alloc_command(struct gsi *gsi, u32 evt_ring_id)
{
enum gsi_evt_ring_state state;
state = gsi_evt_ring_state(gsi, evt_ring_id);
if (state != GSI_EVT_RING_STATE_ALLOCATED) {
dev_err(gsi->dev, "event ring %u state %u before dealloc\n",
evt_ring_id, state);
return;
}
gsi_evt_ring_command(gsi, evt_ring_id, GSI_EVT_DE_ALLOC);
/* If successful the event ring state will have changed */
state = gsi_evt_ring_state(gsi, evt_ring_id);
if (state == GSI_EVT_RING_STATE_NOT_ALLOCATED)
return;
dev_err(gsi->dev, "event ring %u bad state %u after dealloc\n",
evt_ring_id, state);
}
/* Fetch the current state of a channel from hardware */
static enum gsi_channel_state gsi_channel_state(struct gsi_channel *channel)
{
const struct reg *reg = gsi_reg(channel->gsi, CH_C_CNTXT_0);
u32 channel_id = gsi_channel_id(channel);
struct gsi *gsi = channel->gsi;
void __iomem *virt = gsi->virt;
u32 val;
reg = gsi_reg(gsi, CH_C_CNTXT_0);
val = ioread32(virt + reg_n_offset(reg, channel_id));
return reg_decode(reg, CHSTATE, val);
}
/* Issue a channel command and wait for it to complete */
static void
gsi_channel_command(struct gsi_channel *channel, enum gsi_ch_cmd_opcode opcode)
{
u32 channel_id = gsi_channel_id(channel);
struct gsi *gsi = channel->gsi;
struct device *dev = gsi->dev;
const struct reg *reg;
bool timeout;
u32 val;
/* Enable the completion interrupt for the command */
gsi_irq_ch_ctrl_enable(gsi, channel_id);
reg = gsi_reg(gsi, CH_CMD);
val = reg_encode(reg, CH_CHID, channel_id);
val |= reg_encode(reg, CH_OPCODE, opcode);
timeout = !gsi_command(gsi, reg_offset(reg), val);
gsi_irq_ch_ctrl_disable(gsi);
if (!timeout)
return;
dev_err(dev, "GSI command %u for channel %u timed out, state %u\n",
opcode, channel_id, gsi_channel_state(channel));
}
/* Allocate GSI channel in NOT_ALLOCATED state */
static int gsi_channel_alloc_command(struct gsi *gsi, u32 channel_id)
{
struct gsi_channel *channel = &gsi->channel[channel_id];
struct device *dev = gsi->dev;
enum gsi_channel_state state;
/* Get initial channel state */
state = gsi_channel_state(channel);
if (state != GSI_CHANNEL_STATE_NOT_ALLOCATED) {
dev_err(dev, "channel %u bad state %u before alloc\n",
channel_id, state);
return -EINVAL;
}
gsi_channel_command(channel, GSI_CH_ALLOCATE);
/* If successful the channel state will have changed */
state = gsi_channel_state(channel);
if (state == GSI_CHANNEL_STATE_ALLOCATED)
return 0;
dev_err(dev, "channel %u bad state %u after alloc\n",
channel_id, state);
return -EIO;
}
/* Start an ALLOCATED channel */
static int gsi_channel_start_command(struct gsi_channel *channel)
{
struct device *dev = channel->gsi->dev;
enum gsi_channel_state state;
state = gsi_channel_state(channel);
if (state != GSI_CHANNEL_STATE_ALLOCATED &&
state != GSI_CHANNEL_STATE_STOPPED) {
dev_err(dev, "channel %u bad state %u before start\n",
gsi_channel_id(channel), state);
return -EINVAL;
}
gsi_channel_command(channel, GSI_CH_START);
/* If successful the channel state will have changed */
state = gsi_channel_state(channel);
if (state == GSI_CHANNEL_STATE_STARTED)
return 0;
dev_err(dev, "channel %u bad state %u after start\n",
gsi_channel_id(channel), state);
return -EIO;
}
/* Stop a GSI channel in STARTED state */
static int gsi_channel_stop_command(struct gsi_channel *channel)
{
struct device *dev = channel->gsi->dev;
enum gsi_channel_state state;
state = gsi_channel_state(channel);
/* Channel could have entered STOPPED state since last call
* if it timed out. If so, we're done.
*/
if (state == GSI_CHANNEL_STATE_STOPPED)
return 0;
if (state != GSI_CHANNEL_STATE_STARTED &&
state != GSI_CHANNEL_STATE_STOP_IN_PROC) {
dev_err(dev, "channel %u bad state %u before stop\n",
gsi_channel_id(channel), state);
return -EINVAL;
}
gsi_channel_command(channel, GSI_CH_STOP);
/* If successful the channel state will have changed */
state = gsi_channel_state(channel);
if (state == GSI_CHANNEL_STATE_STOPPED)
return 0;
/* We may have to try again if stop is in progress */
if (state == GSI_CHANNEL_STATE_STOP_IN_PROC)
return -EAGAIN;
dev_err(dev, "channel %u bad state %u after stop\n",
gsi_channel_id(channel), state);
return -EIO;
}
/* Reset a GSI channel in ALLOCATED or ERROR state. */
static void gsi_channel_reset_command(struct gsi_channel *channel)
{
struct device *dev = channel->gsi->dev;
enum gsi_channel_state state;
/* A short delay is required before a RESET command */
usleep_range(USEC_PER_MSEC, 2 * USEC_PER_MSEC);
state = gsi_channel_state(channel);
if (state != GSI_CHANNEL_STATE_STOPPED &&
state != GSI_CHANNEL_STATE_ERROR) {
/* No need to reset a channel already in ALLOCATED state */
if (state != GSI_CHANNEL_STATE_ALLOCATED)
dev_err(dev, "channel %u bad state %u before reset\n",
gsi_channel_id(channel), state);
return;
}
gsi_channel_command(channel, GSI_CH_RESET);
/* If successful the channel state will have changed */
state = gsi_channel_state(channel);
if (state != GSI_CHANNEL_STATE_ALLOCATED)
dev_err(dev, "channel %u bad state %u after reset\n",
gsi_channel_id(channel), state);
}
/* Deallocate an ALLOCATED GSI channel */
static void gsi_channel_de_alloc_command(struct gsi *gsi, u32 channel_id)
{
struct gsi_channel *channel = &gsi->channel[channel_id];
struct device *dev = gsi->dev;
enum gsi_channel_state state;
state = gsi_channel_state(channel);
if (state != GSI_CHANNEL_STATE_ALLOCATED) {
dev_err(dev, "channel %u bad state %u before dealloc\n",
channel_id, state);
return;
}
gsi_channel_command(channel, GSI_CH_DE_ALLOC);
/* If successful the channel state will have changed */
state = gsi_channel_state(channel);
if (state != GSI_CHANNEL_STATE_NOT_ALLOCATED)
dev_err(dev, "channel %u bad state %u after dealloc\n",
channel_id, state);
}
/* Ring an event ring doorbell, reporting the last entry processed by the AP.
* The index argument (modulo the ring count) is the first unfilled entry, so
* we supply one less than that with the doorbell. Update the event ring
* index field with the value provided.
*/
static void gsi_evt_ring_doorbell(struct gsi *gsi, u32 evt_ring_id, u32 index)
{
const struct reg *reg = gsi_reg(gsi, EV_CH_E_DOORBELL_0);
struct gsi_ring *ring = &gsi->evt_ring[evt_ring_id].ring;
u32 val;
ring->index = index; /* Next unused entry */
/* Note: index *must* be used modulo the ring count here */
val = gsi_ring_addr(ring, (index - 1) % ring->count);
iowrite32(val, gsi->virt + reg_n_offset(reg, evt_ring_id));
}
/* Program an event ring for use */
static void gsi_evt_ring_program(struct gsi *gsi, u32 evt_ring_id)
{
struct gsi_evt_ring *evt_ring = &gsi->evt_ring[evt_ring_id];
struct gsi_ring *ring = &evt_ring->ring;
const struct reg *reg;
u32 val;
reg = gsi_reg(gsi, EV_CH_E_CNTXT_0);
/* We program all event rings as GPI type/protocol */
val = reg_encode(reg, EV_CHTYPE, GSI_CHANNEL_TYPE_GPI);
/* EV_EE field is 0 (GSI_EE_AP) */
val |= reg_bit(reg, EV_INTYPE);
val |= reg_encode(reg, EV_ELEMENT_SIZE, GSI_RING_ELEMENT_SIZE);
iowrite32(val, gsi->virt + reg_n_offset(reg, evt_ring_id));
reg = gsi_reg(gsi, EV_CH_E_CNTXT_1);
val = reg_encode(reg, R_LENGTH, ring->count * GSI_RING_ELEMENT_SIZE);
iowrite32(val, gsi->virt + reg_n_offset(reg, evt_ring_id));
/* The context 2 and 3 registers store the low-order and
* high-order 32 bits of the address of the event ring,
* respectively.
*/
reg = gsi_reg(gsi, EV_CH_E_CNTXT_2);
val = lower_32_bits(ring->addr);
iowrite32(val, gsi->virt + reg_n_offset(reg, evt_ring_id));
reg = gsi_reg(gsi, EV_CH_E_CNTXT_3);
val = upper_32_bits(ring->addr);
iowrite32(val, gsi->virt + reg_n_offset(reg, evt_ring_id));
/* Enable interrupt moderation by setting the moderation delay */
reg = gsi_reg(gsi, EV_CH_E_CNTXT_8);
val = reg_encode(reg, EV_MODT, GSI_EVT_RING_INT_MODT);
val |= reg_encode(reg, EV_MODC, 1); /* comes from channel */
/* EV_MOD_CNT is 0 (no counter-based interrupt coalescing) */
iowrite32(val, gsi->virt + reg_n_offset(reg, evt_ring_id));
/* No MSI write data, and MSI high and low address is 0 */
reg = gsi_reg(gsi, EV_CH_E_CNTXT_9);
iowrite32(0, gsi->virt + reg_n_offset(reg, evt_ring_id));
reg = gsi_reg(gsi, EV_CH_E_CNTXT_10);
iowrite32(0, gsi->virt + reg_n_offset(reg, evt_ring_id));
reg = gsi_reg(gsi, EV_CH_E_CNTXT_11);
iowrite32(0, gsi->virt + reg_n_offset(reg, evt_ring_id));
/* We don't need to get event read pointer updates */
reg = gsi_reg(gsi, EV_CH_E_CNTXT_12);
iowrite32(0, gsi->virt + reg_n_offset(reg, evt_ring_id));
reg = gsi_reg(gsi, EV_CH_E_CNTXT_13);
iowrite32(0, gsi->virt + reg_n_offset(reg, evt_ring_id));
/* Finally, tell the hardware our "last processed" event (arbitrary) */
gsi_evt_ring_doorbell(gsi, evt_ring_id, ring->index);
}
/* Find the transaction whose completion indicates a channel is quiesced */
static struct gsi_trans *gsi_channel_trans_last(struct gsi_channel *channel)
{
struct gsi_trans_info *trans_info = &channel->trans_info;
u32 pending_id = trans_info->pending_id;
struct gsi_trans *trans;
u16 trans_id;
if (channel->toward_ipa && pending_id != trans_info->free_id) {
/* There is a small chance a TX transaction got allocated
* just before we disabled transmits, so check for that.
* The last allocated, committed, or pending transaction
* precedes the first free transaction.
*/
trans_id = trans_info->free_id - 1;
} else if (trans_info->polled_id != pending_id) {
/* Otherwise (TX or RX) we want to wait for anything that
* has completed, or has been polled but not released yet.
*
* The last completed or polled transaction precedes the
* first pending transaction.
*/
trans_id = pending_id - 1;
} else {
return NULL;
}
/* Caller will wait for this, so take a reference */
trans = &trans_info->trans[trans_id % channel->tre_count];
refcount_inc(&trans->refcount);
return trans;
}
/* Wait for transaction activity on a channel to complete */
static void gsi_channel_trans_quiesce(struct gsi_channel *channel)
{
struct gsi_trans *trans;
/* Get the last transaction, and wait for it to complete */
trans = gsi_channel_trans_last(channel);
if (trans) {
wait_for_completion(&trans->completion);
gsi_trans_free(trans);
}
}
/* Program a channel for use; there is no gsi_channel_deprogram() */
static void gsi_channel_program(struct gsi_channel *channel, bool doorbell)
{
size_t size = channel->tre_ring.count * GSI_RING_ELEMENT_SIZE;
u32 channel_id = gsi_channel_id(channel);
union gsi_channel_scratch scr = { };
struct gsi_channel_scratch_gpi *gpi;
struct gsi *gsi = channel->gsi;
const struct reg *reg;
u32 wrr_weight = 0;
u32 offset;
u32 val;
reg = gsi_reg(gsi, CH_C_CNTXT_0);
/* We program all channels as GPI type/protocol */
val = ch_c_cntxt_0_type_encode(gsi->version, reg, GSI_CHANNEL_TYPE_GPI);
if (channel->toward_ipa)
val |= reg_bit(reg, CHTYPE_DIR);
if (gsi->version < IPA_VERSION_5_0)
val |= reg_encode(reg, ERINDEX, channel->evt_ring_id);
val |= reg_encode(reg, ELEMENT_SIZE, GSI_RING_ELEMENT_SIZE);
iowrite32(val, gsi->virt + reg_n_offset(reg, channel_id));
reg = gsi_reg(gsi, CH_C_CNTXT_1);
val = reg_encode(reg, CH_R_LENGTH, size);
if (gsi->version >= IPA_VERSION_5_0)
val |= reg_encode(reg, CH_ERINDEX, channel->evt_ring_id);
iowrite32(val, gsi->virt + reg_n_offset(reg, channel_id));
/* The context 2 and 3 registers store the low-order and
* high-order 32 bits of the address of the channel ring,
* respectively.
*/
reg = gsi_reg(gsi, CH_C_CNTXT_2);
val = lower_32_bits(channel->tre_ring.addr);
iowrite32(val, gsi->virt + reg_n_offset(reg, channel_id));
reg = gsi_reg(gsi, CH_C_CNTXT_3);
val = upper_32_bits(channel->tre_ring.addr);
iowrite32(val, gsi->virt + reg_n_offset(reg, channel_id));
reg = gsi_reg(gsi, CH_C_QOS);
/* Command channel gets low weighted round-robin priority */
if (channel->command)
wrr_weight = reg_field_max(reg, WRR_WEIGHT);
val = reg_encode(reg, WRR_WEIGHT, wrr_weight);
/* Max prefetch is 1 segment (do not set MAX_PREFETCH_FMASK) */
/* No need to use the doorbell engine starting at IPA v4.0 */
if (gsi->version < IPA_VERSION_4_0 && doorbell)
val |= reg_bit(reg, USE_DB_ENG);
/* v4.0 introduces an escape buffer for prefetch. We use it
* on all but the AP command channel.
*/
if (gsi->version >= IPA_VERSION_4_0 && !channel->command) {
/* If not otherwise set, prefetch buffers are used */
if (gsi->version < IPA_VERSION_4_5)
val |= reg_bit(reg, USE_ESCAPE_BUF_ONLY);
else
val |= reg_encode(reg, PREFETCH_MODE, ESCAPE_BUF_ONLY);
}
/* All channels set DB_IN_BYTES */
if (gsi->version >= IPA_VERSION_4_9)
val |= reg_bit(reg, DB_IN_BYTES);
iowrite32(val, gsi->virt + reg_n_offset(reg, channel_id));
/* Now update the scratch registers for GPI protocol */
gpi = &scr.gpi;
gpi->max_outstanding_tre = channel->trans_tre_max *
GSI_RING_ELEMENT_SIZE;
gpi->outstanding_threshold = 2 * GSI_RING_ELEMENT_SIZE;
reg = gsi_reg(gsi, CH_C_SCRATCH_0);
val = scr.data.word1;
iowrite32(val, gsi->virt + reg_n_offset(reg, channel_id));
reg = gsi_reg(gsi, CH_C_SCRATCH_1);
val = scr.data.word2;
iowrite32(val, gsi->virt + reg_n_offset(reg, channel_id));
reg = gsi_reg(gsi, CH_C_SCRATCH_2);
val = scr.data.word3;
iowrite32(val, gsi->virt + reg_n_offset(reg, channel_id));
/* We must preserve the upper 16 bits of the last scratch register.
* The next sequence assumes those bits remain unchanged between the
* read and the write.
*/
reg = gsi_reg(gsi, CH_C_SCRATCH_3);
offset = reg_n_offset(reg, channel_id);
val = ioread32(gsi->virt + offset);
val = (scr.data.word4 & GENMASK(31, 16)) | (val & GENMASK(15, 0));
iowrite32(val, gsi->virt + offset);
/* All done! */
}
static int __gsi_channel_start(struct gsi_channel *channel, bool resume)
{
struct gsi *gsi = channel->gsi;
int ret;
/* Prior to IPA v4.0 suspend/resume is not implemented by GSI */
if (resume && gsi->version < IPA_VERSION_4_0)
return 0;
mutex_lock(&gsi->mutex);
ret = gsi_channel_start_command(channel);
mutex_unlock(&gsi->mutex);
return ret;
}
/* Start an allocated GSI channel */
int gsi_channel_start(struct gsi *gsi, u32 channel_id)
{
struct gsi_channel *channel = &gsi->channel[channel_id];
int ret;
/* Enable NAPI and the completion interrupt */
napi_enable(&channel->napi);
gsi_irq_ieob_enable_one(gsi, channel->evt_ring_id);
ret = __gsi_channel_start(channel, false);
if (ret) {
gsi_irq_ieob_disable_one(gsi, channel->evt_ring_id);
napi_disable(&channel->napi);
}
return ret;
}
static int gsi_channel_stop_retry(struct gsi_channel *channel)
{
u32 retries = GSI_CHANNEL_STOP_RETRIES;
int ret;
do {
ret = gsi_channel_stop_command(channel);
if (ret != -EAGAIN)
break;
usleep_range(3 * USEC_PER_MSEC, 5 * USEC_PER_MSEC);
} while (retries--);
return ret;
}
static int __gsi_channel_stop(struct gsi_channel *channel, bool suspend)
{
struct gsi *gsi = channel->gsi;
int ret;
/* Wait for any underway transactions to complete before stopping. */
gsi_channel_trans_quiesce(channel);
/* Prior to IPA v4.0 suspend/resume is not implemented by GSI */
if (suspend && gsi->version < IPA_VERSION_4_0)
return 0;
mutex_lock(&gsi->mutex);
ret = gsi_channel_stop_retry(channel);
mutex_unlock(&gsi->mutex);
return ret;
}
/* Stop a started channel */
int gsi_channel_stop(struct gsi *gsi, u32 channel_id)
{
struct gsi_channel *channel = &gsi->channel[channel_id];
int ret;
ret = __gsi_channel_stop(channel, false);
if (ret)
return ret;
/* Disable the completion interrupt and NAPI if successful */
gsi_irq_ieob_disable_one(gsi, channel->evt_ring_id);
napi_disable(&channel->napi);
return 0;
}
/* Reset and reconfigure a channel, (possibly) enabling the doorbell engine */
void gsi_channel_reset(struct gsi *gsi, u32 channel_id, bool doorbell)
{
struct gsi_channel *channel = &gsi->channel[channel_id];
mutex_lock(&gsi->mutex);
gsi_channel_reset_command(channel);
/* Due to a hardware quirk we may need to reset RX channels twice. */
if (gsi->version < IPA_VERSION_4_0 && !channel->toward_ipa)
gsi_channel_reset_command(channel);
/* Hardware assumes this is 0 following reset */
channel->tre_ring.index = 0;
gsi_channel_program(channel, doorbell);
gsi_channel_trans_cancel_pending(channel);
mutex_unlock(&gsi->mutex);
}
/* Stop a started channel for suspend */
int gsi_channel_suspend(struct gsi *gsi, u32 channel_id)
{
struct gsi_channel *channel = &gsi->channel[channel_id];
int ret;
ret = __gsi_channel_stop(channel, true);
if (ret)
return ret;
/* Ensure NAPI polling has finished. */
napi_synchronize(&channel->napi);
return 0;
}
/* Resume a suspended channel (starting if stopped) */
int gsi_channel_resume(struct gsi *gsi, u32 channel_id)
{
struct gsi_channel *channel = &gsi->channel[channel_id];
return __gsi_channel_start(channel, true);
}
/* Prevent all GSI interrupts while suspended */
void gsi_suspend(struct gsi *gsi)
{
disable_irq(gsi->irq);
}
/* Allow all GSI interrupts again when resuming */
void gsi_resume(struct gsi *gsi)
{
enable_irq(gsi->irq);
}
void gsi_trans_tx_committed(struct gsi_trans *trans)
{
struct gsi_channel *channel = &trans->gsi->channel[trans->channel_id];
channel->trans_count++;
channel->byte_count += trans->len;
trans->trans_count = channel->trans_count;
trans->byte_count = channel->byte_count;
}
void gsi_trans_tx_queued(struct gsi_trans *trans)
{
u32 channel_id = trans->channel_id;
struct gsi *gsi = trans->gsi;
struct gsi_channel *channel;
u32 trans_count;
u32 byte_count;
channel = &gsi->channel[channel_id];
byte_count = channel->byte_count - channel->queued_byte_count;
trans_count = channel->trans_count - channel->queued_trans_count;
channel->queued_byte_count = channel->byte_count;
channel->queued_trans_count = channel->trans_count;
ipa_gsi_channel_tx_queued(gsi, channel_id, trans_count, byte_count);
}
/**
* gsi_trans_tx_completed() - Report completed TX transactions
* @trans: TX channel transaction that has completed
*
* Report that a transaction on a TX channel has completed. At the time a
* transaction is committed, we record *in the transaction* its channel's
* committed transaction and byte counts. Transactions are completed in
* order, and the difference between the channel's byte/transaction count
* when the transaction was committed and when it completes tells us
* exactly how much data has been transferred while the transaction was
* pending.
*
* We report this information to the network stack, which uses it to manage
* the rate at which data is sent to hardware.
*/
static void gsi_trans_tx_completed(struct gsi_trans *trans)
{
u32 channel_id = trans->channel_id;
struct gsi *gsi = trans->gsi;
struct gsi_channel *channel;
u32 trans_count;
u32 byte_count;
channel = &gsi->channel[channel_id];
trans_count = trans->trans_count - channel->compl_trans_count;
byte_count = trans->byte_count - channel->compl_byte_count;
channel->compl_trans_count += trans_count;
channel->compl_byte_count += byte_count;
ipa_gsi_channel_tx_completed(gsi, channel_id, trans_count, byte_count);
}
/* Channel control interrupt handler */
static void gsi_isr_chan_ctrl(struct gsi *gsi)
{
const struct reg *reg;
u32 channel_mask;
reg = gsi_reg(gsi, CNTXT_SRC_CH_IRQ);
channel_mask = ioread32(gsi->virt + reg_offset(reg));
reg = gsi_reg(gsi, CNTXT_SRC_CH_IRQ_CLR);
iowrite32(channel_mask, gsi->virt + reg_offset(reg));
while (channel_mask) {
u32 channel_id = __ffs(channel_mask);
channel_mask ^= BIT(channel_id);
complete(&gsi->completion);
}
}
/* Event ring control interrupt handler */
static void gsi_isr_evt_ctrl(struct gsi *gsi)
{
const struct reg *reg;
u32 event_mask;
reg = gsi_reg(gsi, CNTXT_SRC_EV_CH_IRQ);
event_mask = ioread32(gsi->virt + reg_offset(reg));
reg = gsi_reg(gsi, CNTXT_SRC_EV_CH_IRQ_CLR);
iowrite32(event_mask, gsi->virt + reg_offset(reg));
while (event_mask) {
u32 evt_ring_id = __ffs(event_mask);
event_mask ^= BIT(evt_ring_id);
complete(&gsi->completion);
}
}
/* Global channel error interrupt handler */
static void
gsi_isr_glob_chan_err(struct gsi *gsi, u32 err_ee, u32 channel_id, u32 code)
{
if (code == GSI_OUT_OF_RESOURCES) {
dev_err(gsi->dev, "channel %u out of resources\n", channel_id);
complete(&gsi->completion);
return;
}
/* Report, but otherwise ignore all other error codes */
dev_err(gsi->dev, "channel %u global error ee 0x%08x code 0x%08x\n",
channel_id, err_ee, code);
}
/* Global event error interrupt handler */
static void
gsi_isr_glob_evt_err(struct gsi *gsi, u32 err_ee, u32 evt_ring_id, u32 code)
{
if (code == GSI_OUT_OF_RESOURCES) {
struct gsi_evt_ring *evt_ring = &gsi->evt_ring[evt_ring_id];
u32 channel_id = gsi_channel_id(evt_ring->channel);
complete(&gsi->completion);
dev_err(gsi->dev, "evt_ring for channel %u out of resources\n",
channel_id);
return;
}
/* Report, but otherwise ignore all other error codes */
dev_err(gsi->dev, "event ring %u global error ee %u code 0x%08x\n",
evt_ring_id, err_ee, code);
}
/* Global error interrupt handler */
static void gsi_isr_glob_err(struct gsi *gsi)
{
const struct reg *log_reg;
const struct reg *clr_reg;
enum gsi_err_type type;
enum gsi_err_code code;
u32 offset;
u32 which;
u32 val;
u32 ee;
/* Get the logged error, then reinitialize the log */
log_reg = gsi_reg(gsi, ERROR_LOG);
offset = reg_offset(log_reg);
val = ioread32(gsi->virt + offset);
iowrite32(0, gsi->virt + offset);
clr_reg = gsi_reg(gsi, ERROR_LOG_CLR);
iowrite32(~0, gsi->virt + reg_offset(clr_reg));
/* Parse the error value */
ee = reg_decode(log_reg, ERR_EE, val);
type = reg_decode(log_reg, ERR_TYPE, val);
which = reg_decode(log_reg, ERR_VIRT_IDX, val);
code = reg_decode(log_reg, ERR_CODE, val);
if (type == GSI_ERR_TYPE_CHAN)
gsi_isr_glob_chan_err(gsi, ee, which, code);
else if (type == GSI_ERR_TYPE_EVT)
gsi_isr_glob_evt_err(gsi, ee, which, code);
else /* type GSI_ERR_TYPE_GLOB should be fatal */
dev_err(gsi->dev, "unexpected global error 0x%08x\n", type);
}
/* Generic EE interrupt handler */
static void gsi_isr_gp_int1(struct gsi *gsi)
{
const struct reg *reg;
u32 result;
u32 val;
/* This interrupt is used to handle completions of GENERIC GSI
* commands. We use these to allocate and halt channels on the
* modem's behalf due to a hardware quirk on IPA v4.2. The modem
* "owns" channels even when the AP allocates them, and have no
* way of knowing whether a modem channel's state has been changed.
*
* We also use GENERIC commands to enable/disable channel flow
* control for IPA v4.2+.
*
* It is recommended that we halt the modem channels we allocated
* when shutting down, but it's possible the channel isn't running
* at the time we issue the HALT command. We'll get an error in
* that case, but it's harmless (the channel is already halted).
* Similarly, we could get an error back when updating flow control
* on a channel because it's not in the proper state.
*
* In either case, we silently ignore a INCORRECT_CHANNEL_STATE
* error if we receive it.
*/
reg = gsi_reg(gsi, CNTXT_SCRATCH_0);
val = ioread32(gsi->virt + reg_offset(reg));
result = reg_decode(reg, GENERIC_EE_RESULT, val);
switch (result) {
case GENERIC_EE_SUCCESS:
case GENERIC_EE_INCORRECT_CHANNEL_STATE:
gsi->result = 0;
break;
case GENERIC_EE_RETRY:
gsi->result = -EAGAIN;
break;
default:
dev_err(gsi->dev, "global INT1 generic result %u\n", result);
gsi->result = -EIO;
break;
}
complete(&gsi->completion);
}
/* Inter-EE interrupt handler */
static void gsi_isr_glob_ee(struct gsi *gsi)
{
const struct reg *reg;
u32 val;
reg = gsi_reg(gsi, CNTXT_GLOB_IRQ_STTS);
val = ioread32(gsi->virt + reg_offset(reg));
if (val & ERROR_INT)
gsi_isr_glob_err(gsi);
reg = gsi_reg(gsi, CNTXT_GLOB_IRQ_CLR);
iowrite32(val, gsi->virt + reg_offset(reg));
val &= ~ERROR_INT;
if (val & GP_INT1) {
val ^= GP_INT1;
gsi_isr_gp_int1(gsi);
}
if (val)
dev_err(gsi->dev, "unexpected global interrupt 0x%08x\n", val);
}
/* I/O completion interrupt event */
static void gsi_isr_ieob(struct gsi *gsi)
{
const struct reg *reg;
u32 event_mask;
reg = gsi_reg(gsi, CNTXT_SRC_IEOB_IRQ);
event_mask = ioread32(gsi->virt + reg_offset(reg));
gsi_irq_ieob_disable(gsi, event_mask);
reg = gsi_reg(gsi, CNTXT_SRC_IEOB_IRQ_CLR);
iowrite32(event_mask, gsi->virt + reg_offset(reg));
while (event_mask) {
u32 evt_ring_id = __ffs(event_mask);
event_mask ^= BIT(evt_ring_id);
napi_schedule(&gsi->evt_ring[evt_ring_id].channel->napi);
}
}
/* General event interrupts represent serious problems, so report them */
static void gsi_isr_general(struct gsi *gsi)
{
struct device *dev = gsi->dev;
const struct reg *reg;
u32 val;
reg = gsi_reg(gsi, CNTXT_GSI_IRQ_STTS);
val = ioread32(gsi->virt + reg_offset(reg));
reg = gsi_reg(gsi, CNTXT_GSI_IRQ_CLR);
iowrite32(val, gsi->virt + reg_offset(reg));
dev_err(dev, "unexpected general interrupt 0x%08x\n", val);
}
/**
* gsi_isr() - Top level GSI interrupt service routine
* @irq: Interrupt number (ignored)
* @dev_id: GSI pointer supplied to request_irq()
*
* This is the main handler function registered for the GSI IRQ. Each type
* of interrupt has a separate handler function that is called from here.
*/
static irqreturn_t gsi_isr(int irq, void *dev_id)
{
struct gsi *gsi = dev_id;
const struct reg *reg;
u32 intr_mask;
u32 cnt = 0;
u32 offset;
reg = gsi_reg(gsi, CNTXT_TYPE_IRQ);
offset = reg_offset(reg);
/* enum gsi_irq_type_id defines GSI interrupt types */
while ((intr_mask = ioread32(gsi->virt + offset))) {
/* intr_mask contains bitmask of pending GSI interrupts */
do {
u32 gsi_intr = BIT(__ffs(intr_mask));
intr_mask ^= gsi_intr;
/* Note: the IRQ condition for each type is cleared
* when the type-specific register is updated.
*/
switch (gsi_intr) {
case GSI_CH_CTRL:
gsi_isr_chan_ctrl(gsi);
break;
case GSI_EV_CTRL:
gsi_isr_evt_ctrl(gsi);
break;
case GSI_GLOB_EE:
gsi_isr_glob_ee(gsi);
break;
case GSI_IEOB:
gsi_isr_ieob(gsi);
break;
case GSI_GENERAL:
gsi_isr_general(gsi);
break;
default:
dev_err(gsi->dev,
"unrecognized interrupt type 0x%08x\n",
gsi_intr);
break;
}
} while (intr_mask);
if (++cnt > GSI_ISR_MAX_ITER) {
dev_err(gsi->dev, "interrupt flood\n");
break;
}
}
return IRQ_HANDLED;
}
/* Init function for GSI IRQ lookup; there is no gsi_irq_exit() */
static int gsi_irq_init(struct gsi *gsi, struct platform_device *pdev)
{
int ret;
ret = platform_get_irq_byname(pdev, "gsi");
if (ret <= 0)
return ret ? : -EINVAL;
gsi->irq = ret;
return 0;
}
/* Return the transaction associated with a transfer completion event */
static struct gsi_trans *
gsi_event_trans(struct gsi *gsi, struct gsi_event *event)
{
u32 channel_id = event->chid;
struct gsi_channel *channel;
struct gsi_trans *trans;
u32 tre_offset;
u32 tre_index;
channel = &gsi->channel[channel_id];
if (WARN(!channel->gsi, "event has bad channel %u\n", channel_id))
return NULL;
/* Event xfer_ptr records the TRE it's associated with */
tre_offset = lower_32_bits(le64_to_cpu(event->xfer_ptr));
tre_index = gsi_ring_index(&channel->tre_ring, tre_offset);
trans = gsi_channel_trans_mapped(channel, tre_index);
if (WARN(!trans, "channel %u event with no transaction\n", channel_id))
return NULL;
return trans;
}
/**
* gsi_evt_ring_update() - Update transaction state from hardware
* @gsi: GSI pointer
* @evt_ring_id: Event ring ID
* @index: Event index in ring reported by hardware
*
* Events for RX channels contain the actual number of bytes received into
* the buffer. Every event has a transaction associated with it, and here
* we update transactions to record their actual received lengths.
*
* When an event for a TX channel arrives we use information in the
* transaction to report the number of requests and bytes that have
* been transferred.
*
* This function is called whenever we learn that the GSI hardware has filled
* new events since the last time we checked. The ring's index field tells
* the first entry in need of processing. The index provided is the
* first *unfilled* event in the ring (following the last filled one).
*
* Events are sequential within the event ring, and transactions are
* sequential within the transaction array.
*
* Note that @index always refers to an element *within* the event ring.
*/
static void gsi_evt_ring_update(struct gsi *gsi, u32 evt_ring_id, u32 index)
{
struct gsi_evt_ring *evt_ring = &gsi->evt_ring[evt_ring_id];
struct gsi_ring *ring = &evt_ring->ring;
struct gsi_event *event_done;
struct gsi_event *event;
u32 event_avail;
u32 old_index;
/* Starting with the oldest un-processed event, determine which
* transaction (and which channel) is associated with the event.
* For RX channels, update each completed transaction with the
* number of bytes that were actually received. For TX channels
* associated with a network device, report to the network stack
* the number of transfers and bytes this completion represents.
*/
old_index = ring->index;
event = gsi_ring_virt(ring, old_index);
/* Compute the number of events to process before we wrap,
* and determine when we'll be done processing events.
*/
event_avail = ring->count - old_index % ring->count;
event_done = gsi_ring_virt(ring, index);
do {
struct gsi_trans *trans;
trans = gsi_event_trans(gsi, event);
if (!trans)
return;
if (trans->direction == DMA_FROM_DEVICE)
trans->len = __le16_to_cpu(event->len);
else
gsi_trans_tx_completed(trans);
gsi_trans_move_complete(trans);
/* Move on to the next event and transaction */
if (--event_avail)
event++;
else
event = gsi_ring_virt(ring, 0);
} while (event != event_done);
/* Tell the hardware we've handled these events */
gsi_evt_ring_doorbell(gsi, evt_ring_id, index);
}
/* Initialize a ring, including allocating DMA memory for its entries */
static int gsi_ring_alloc(struct gsi *gsi, struct gsi_ring *ring, u32 count)
{
u32 size = count * GSI_RING_ELEMENT_SIZE;
struct device *dev = gsi->dev;
dma_addr_t addr;
/* Hardware requires a 2^n ring size, with alignment equal to size.
* The DMA address returned by dma_alloc_coherent() is guaranteed to
* be a power-of-2 number of pages, which satisfies the requirement.
*/
ring->virt = dma_alloc_coherent(dev, size, &addr, GFP_KERNEL);
if (!ring->virt)
return -ENOMEM;
ring->addr = addr;
ring->count = count;
ring->index = 0;
return 0;
}
/* Free a previously-allocated ring */
static void gsi_ring_free(struct gsi *gsi, struct gsi_ring *ring)
{
size_t size = ring->count * GSI_RING_ELEMENT_SIZE;
dma_free_coherent(gsi->dev, size, ring->virt, ring->addr);
}
/* Allocate an available event ring id */
static int gsi_evt_ring_id_alloc(struct gsi *gsi)
{
u32 evt_ring_id;
if (gsi->event_bitmap == ~0U) {
dev_err(gsi->dev, "event rings exhausted\n");
return -ENOSPC;
}
evt_ring_id = ffz(gsi->event_bitmap);
gsi->event_bitmap |= BIT(evt_ring_id);
return (int)evt_ring_id;
}
/* Free a previously-allocated event ring id */
static void gsi_evt_ring_id_free(struct gsi *gsi, u32 evt_ring_id)
{
gsi->event_bitmap &= ~BIT(evt_ring_id);
}
/* Ring a channel doorbell, reporting the first un-filled entry */
void gsi_channel_doorbell(struct gsi_channel *channel)
{
struct gsi_ring *tre_ring = &channel->tre_ring;
u32 channel_id = gsi_channel_id(channel);
struct gsi *gsi = channel->gsi;
const struct reg *reg;
u32 val;
reg = gsi_reg(gsi, CH_C_DOORBELL_0);
/* Note: index *must* be used modulo the ring count here */
val = gsi_ring_addr(tre_ring, tre_ring->index % tre_ring->count);
iowrite32(val, gsi->virt + reg_n_offset(reg, channel_id));
}
/* Consult hardware, move newly completed transactions to completed state */
void gsi_channel_update(struct gsi_channel *channel)
{
u32 evt_ring_id = channel->evt_ring_id;
struct gsi *gsi = channel->gsi;
struct gsi_evt_ring *evt_ring;
struct gsi_trans *trans;
struct gsi_ring *ring;
const struct reg *reg;
u32 offset;
u32 index;
evt_ring = &gsi->evt_ring[evt_ring_id];
ring = &evt_ring->ring;
/* See if there's anything new to process; if not, we're done. Note
* that index always refers to an entry *within* the event ring.
*/
reg = gsi_reg(gsi, EV_CH_E_CNTXT_4);
offset = reg_n_offset(reg, evt_ring_id);
index = gsi_ring_index(ring, ioread32(gsi->virt + offset));
if (index == ring->index % ring->count)
return;
/* Get the transaction for the latest completed event. */
trans = gsi_event_trans(gsi, gsi_ring_virt(ring, index - 1));
if (!trans)
return;
/* For RX channels, update each completed transaction with the number
* of bytes that were actually received. For TX channels, report
* the number of transactions and bytes this completion represents
* up the network stack.
*/
gsi_evt_ring_update(gsi, evt_ring_id, index);
}
/**
* gsi_channel_poll_one() - Return a single completed transaction on a channel
* @channel: Channel to be polled
*
* Return: Transaction pointer, or null if none are available
*
* This function returns the first of a channel's completed transactions.
* If no transactions are in completed state, the hardware is consulted to
* determine whether any new transactions have completed. If so, they're
* moved to completed state and the first such transaction is returned.
* If there are no more completed transactions, a null pointer is returned.
*/
static struct gsi_trans *gsi_channel_poll_one(struct gsi_channel *channel)
{
struct gsi_trans *trans;
/* Get the first completed transaction */
trans = gsi_channel_trans_complete(channel);
if (trans)
gsi_trans_move_polled(trans);
return trans;
}
/**
* gsi_channel_poll() - NAPI poll function for a channel
* @napi: NAPI structure for the channel
* @budget: Budget supplied by NAPI core
*
* Return: Number of items polled (<= budget)
*
* Single transactions completed by hardware are polled until either
* the budget is exhausted, or there are no more. Each transaction
* polled is passed to gsi_trans_complete(), to perform remaining
* completion processing and retire/free the transaction.
*/
static int gsi_channel_poll(struct napi_struct *napi, int budget)
{
struct gsi_channel *channel;
int count;
channel = container_of(napi, struct gsi_channel, napi);
for (count = 0; count < budget; count++) {
struct gsi_trans *trans;
trans = gsi_channel_poll_one(channel);
if (!trans)
break;
gsi_trans_complete(trans);
}
if (count < budget && napi_complete(napi))
gsi_irq_ieob_enable_one(channel->gsi, channel->evt_ring_id);
return count;
}
/* The event bitmap represents which event ids are available for allocation.
* Set bits are not available, clear bits can be used. This function
* initializes the map so all events supported by the hardware are available,
* then precludes any reserved events from being allocated.
*/
static u32 gsi_event_bitmap_init(u32 evt_ring_max)
{
u32 event_bitmap = GENMASK(BITS_PER_LONG - 1, evt_ring_max);
event_bitmap |= GENMASK(GSI_MHI_EVENT_ID_END, GSI_MHI_EVENT_ID_START);
return event_bitmap;
}
/* Setup function for a single channel */
static int gsi_channel_setup_one(struct gsi *gsi, u32 channel_id)
{
struct gsi_channel *channel = &gsi->channel[channel_id];
u32 evt_ring_id = channel->evt_ring_id;
int ret;
if (!gsi_channel_initialized(channel))
return 0;
ret = gsi_evt_ring_alloc_command(gsi, evt_ring_id);
if (ret)
return ret;
gsi_evt_ring_program(gsi, evt_ring_id);
ret = gsi_channel_alloc_command(gsi, channel_id);
if (ret)
goto err_evt_ring_de_alloc;
gsi_channel_program(channel, true);
if (channel->toward_ipa)
netif_napi_add_tx(&gsi->dummy_dev, &channel->napi,
gsi_channel_poll);
else
netif_napi_add(&gsi->dummy_dev, &channel->napi,
gsi_channel_poll);
return 0;
err_evt_ring_de_alloc:
/* We've done nothing with the event ring yet so don't reset */
gsi_evt_ring_de_alloc_command(gsi, evt_ring_id);
return ret;
}
/* Inverse of gsi_channel_setup_one() */
static void gsi_channel_teardown_one(struct gsi *gsi, u32 channel_id)
{
struct gsi_channel *channel = &gsi->channel[channel_id];
u32 evt_ring_id = channel->evt_ring_id;
if (!gsi_channel_initialized(channel))
return;
netif_napi_del(&channel->napi);
gsi_channel_de_alloc_command(gsi, channel_id);
gsi_evt_ring_reset_command(gsi, evt_ring_id);
gsi_evt_ring_de_alloc_command(gsi, evt_ring_id);
}
/* We use generic commands only to operate on modem channels. We don't have
* the ability to determine channel state for a modem channel, so we simply
* issue the command and wait for it to complete.
*/
static int gsi_generic_command(struct gsi *gsi, u32 channel_id,
net: ipa: support enhanced channel flow control IPA v4.2 introduced GSI channel flow control, used instead of IPA endpoint DELAY mode to prevent a TX channel from injecting packets into the IPA core. It used a new FLOW_CONTROLLED channel state which could be entered using GSI generic commands. IPA v4.11 extended the channel flow control model. Rather than having a distinct FLOW_CONTROLLED channel state, each channel has a "flow control" property that can be enabled or not--independent of the channel state. The AP (or modem) can modify this property using the same GSI generic commands as before. The AP only uses channel flow control on modem TX channels, and only when recovering from a modem crash. The AP has no way to discover the state of a modem channel, so the fact that (starting with IPA v4.11) flow control no longer uses a distinct channel state is invisible to the AP. So enhanced flow control generally does not change the way AP uses flow control. There are a few small differences, however: - There is a notion of "primary" or "secondary" flow control, and when enabling or disabling flow control that must be specified in a new field in the GSI generic command register. For now, we always specify 0 (meaning "primary"). - When disabling flow control, it's possible a request will need to be retried. We retry up to 5 times in this case. - Another new generic command allows the current flow control state to be queried. We do not use this. Other than the need for retries, the code essentially works the same way as before. Signed-off-by: Alex Elder <elder@linaro.org> Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2021-11-25 03:44:16 +08:00
enum gsi_generic_cmd_opcode opcode,
u8 params)
{
const struct reg *reg;
bool timeout;
u32 offset;
u32 val;
/* The error global interrupt type is always enabled (until we tear
* down), so we will keep it enabled.
*
* A generic EE command completes with a GSI global interrupt of
* type GP_INT1. We only perform one generic command at a time
* (to allocate, halt, or enable/disable flow control on a modem
* channel), and only from this function. So we enable the GP_INT1
* IRQ type here, and disable it again after the command completes.
*/
reg = gsi_reg(gsi, CNTXT_GLOB_IRQ_EN);
val = ERROR_INT | GP_INT1;
iowrite32(val, gsi->virt + reg_offset(reg));
/* First zero the result code field */
reg = gsi_reg(gsi, CNTXT_SCRATCH_0);
offset = reg_offset(reg);
val = ioread32(gsi->virt + offset);
val &= ~reg_fmask(reg, GENERIC_EE_RESULT);
iowrite32(val, gsi->virt + offset);
/* Now issue the command */
reg = gsi_reg(gsi, GENERIC_CMD);
val = reg_encode(reg, GENERIC_OPCODE, opcode);
val |= reg_encode(reg, GENERIC_CHID, channel_id);
val |= reg_encode(reg, GENERIC_EE, GSI_EE_MODEM);
if (gsi->version >= IPA_VERSION_4_11)
val |= reg_encode(reg, GENERIC_PARAMS, params);
timeout = !gsi_command(gsi, reg_offset(reg), val);
/* Disable the GP_INT1 IRQ type again */
reg = gsi_reg(gsi, CNTXT_GLOB_IRQ_EN);
iowrite32(ERROR_INT, gsi->virt + reg_offset(reg));
if (!timeout)
return gsi->result;
dev_err(gsi->dev, "GSI generic command %u to channel %u timed out\n",
opcode, channel_id);
return -ETIMEDOUT;
}
static int gsi_modem_channel_alloc(struct gsi *gsi, u32 channel_id)
{
return gsi_generic_command(gsi, channel_id,
net: ipa: support enhanced channel flow control IPA v4.2 introduced GSI channel flow control, used instead of IPA endpoint DELAY mode to prevent a TX channel from injecting packets into the IPA core. It used a new FLOW_CONTROLLED channel state which could be entered using GSI generic commands. IPA v4.11 extended the channel flow control model. Rather than having a distinct FLOW_CONTROLLED channel state, each channel has a "flow control" property that can be enabled or not--independent of the channel state. The AP (or modem) can modify this property using the same GSI generic commands as before. The AP only uses channel flow control on modem TX channels, and only when recovering from a modem crash. The AP has no way to discover the state of a modem channel, so the fact that (starting with IPA v4.11) flow control no longer uses a distinct channel state is invisible to the AP. So enhanced flow control generally does not change the way AP uses flow control. There are a few small differences, however: - There is a notion of "primary" or "secondary" flow control, and when enabling or disabling flow control that must be specified in a new field in the GSI generic command register. For now, we always specify 0 (meaning "primary"). - When disabling flow control, it's possible a request will need to be retried. We retry up to 5 times in this case. - Another new generic command allows the current flow control state to be queried. We do not use this. Other than the need for retries, the code essentially works the same way as before. Signed-off-by: Alex Elder <elder@linaro.org> Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2021-11-25 03:44:16 +08:00
GSI_GENERIC_ALLOCATE_CHANNEL, 0);
}
static void gsi_modem_channel_halt(struct gsi *gsi, u32 channel_id)
{
u32 retries = GSI_CHANNEL_MODEM_HALT_RETRIES;
int ret;
do
ret = gsi_generic_command(gsi, channel_id,
net: ipa: support enhanced channel flow control IPA v4.2 introduced GSI channel flow control, used instead of IPA endpoint DELAY mode to prevent a TX channel from injecting packets into the IPA core. It used a new FLOW_CONTROLLED channel state which could be entered using GSI generic commands. IPA v4.11 extended the channel flow control model. Rather than having a distinct FLOW_CONTROLLED channel state, each channel has a "flow control" property that can be enabled or not--independent of the channel state. The AP (or modem) can modify this property using the same GSI generic commands as before. The AP only uses channel flow control on modem TX channels, and only when recovering from a modem crash. The AP has no way to discover the state of a modem channel, so the fact that (starting with IPA v4.11) flow control no longer uses a distinct channel state is invisible to the AP. So enhanced flow control generally does not change the way AP uses flow control. There are a few small differences, however: - There is a notion of "primary" or "secondary" flow control, and when enabling or disabling flow control that must be specified in a new field in the GSI generic command register. For now, we always specify 0 (meaning "primary"). - When disabling flow control, it's possible a request will need to be retried. We retry up to 5 times in this case. - Another new generic command allows the current flow control state to be queried. We do not use this. Other than the need for retries, the code essentially works the same way as before. Signed-off-by: Alex Elder <elder@linaro.org> Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2021-11-25 03:44:16 +08:00
GSI_GENERIC_HALT_CHANNEL, 0);
while (ret == -EAGAIN && retries--);
if (ret)
dev_err(gsi->dev, "error %d halting modem channel %u\n",
ret, channel_id);
}
/* Enable or disable flow control for a modem GSI TX channel (IPA v4.2+) */
void
gsi_modem_channel_flow_control(struct gsi *gsi, u32 channel_id, bool enable)
{
net: ipa: support enhanced channel flow control IPA v4.2 introduced GSI channel flow control, used instead of IPA endpoint DELAY mode to prevent a TX channel from injecting packets into the IPA core. It used a new FLOW_CONTROLLED channel state which could be entered using GSI generic commands. IPA v4.11 extended the channel flow control model. Rather than having a distinct FLOW_CONTROLLED channel state, each channel has a "flow control" property that can be enabled or not--independent of the channel state. The AP (or modem) can modify this property using the same GSI generic commands as before. The AP only uses channel flow control on modem TX channels, and only when recovering from a modem crash. The AP has no way to discover the state of a modem channel, so the fact that (starting with IPA v4.11) flow control no longer uses a distinct channel state is invisible to the AP. So enhanced flow control generally does not change the way AP uses flow control. There are a few small differences, however: - There is a notion of "primary" or "secondary" flow control, and when enabling or disabling flow control that must be specified in a new field in the GSI generic command register. For now, we always specify 0 (meaning "primary"). - When disabling flow control, it's possible a request will need to be retried. We retry up to 5 times in this case. - Another new generic command allows the current flow control state to be queried. We do not use this. Other than the need for retries, the code essentially works the same way as before. Signed-off-by: Alex Elder <elder@linaro.org> Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2021-11-25 03:44:16 +08:00
u32 retries = 0;
u32 command;
int ret;
command = enable ? GSI_GENERIC_ENABLE_FLOW_CONTROL
: GSI_GENERIC_DISABLE_FLOW_CONTROL;
net: ipa: support enhanced channel flow control IPA v4.2 introduced GSI channel flow control, used instead of IPA endpoint DELAY mode to prevent a TX channel from injecting packets into the IPA core. It used a new FLOW_CONTROLLED channel state which could be entered using GSI generic commands. IPA v4.11 extended the channel flow control model. Rather than having a distinct FLOW_CONTROLLED channel state, each channel has a "flow control" property that can be enabled or not--independent of the channel state. The AP (or modem) can modify this property using the same GSI generic commands as before. The AP only uses channel flow control on modem TX channels, and only when recovering from a modem crash. The AP has no way to discover the state of a modem channel, so the fact that (starting with IPA v4.11) flow control no longer uses a distinct channel state is invisible to the AP. So enhanced flow control generally does not change the way AP uses flow control. There are a few small differences, however: - There is a notion of "primary" or "secondary" flow control, and when enabling or disabling flow control that must be specified in a new field in the GSI generic command register. For now, we always specify 0 (meaning "primary"). - When disabling flow control, it's possible a request will need to be retried. We retry up to 5 times in this case. - Another new generic command allows the current flow control state to be queried. We do not use this. Other than the need for retries, the code essentially works the same way as before. Signed-off-by: Alex Elder <elder@linaro.org> Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2021-11-25 03:44:16 +08:00
/* Disabling flow control on IPA v4.11+ can return -EAGAIN if enable
* is underway. In this case we need to retry the command.
*/
if (!enable && gsi->version >= IPA_VERSION_4_11)
retries = GSI_CHANNEL_MODEM_FLOW_RETRIES;
do
ret = gsi_generic_command(gsi, channel_id, command, 0);
while (ret == -EAGAIN && retries--);
if (ret)
dev_err(gsi->dev,
"error %d %sabling mode channel %u flow control\n",
ret, enable ? "en" : "dis", channel_id);
}
/* Setup function for channels */
static int gsi_channel_setup(struct gsi *gsi)
{
u32 channel_id = 0;
u32 mask;
int ret;
gsi_irq_enable(gsi);
mutex_lock(&gsi->mutex);
do {
ret = gsi_channel_setup_one(gsi, channel_id);
if (ret)
goto err_unwind;
} while (++channel_id < gsi->channel_count);
/* Make sure no channels were defined that hardware does not support */
while (channel_id < GSI_CHANNEL_COUNT_MAX) {
struct gsi_channel *channel = &gsi->channel[channel_id++];
if (!gsi_channel_initialized(channel))
continue;
ret = -EINVAL;
dev_err(gsi->dev, "channel %u not supported by hardware\n",
channel_id - 1);
channel_id = gsi->channel_count;
goto err_unwind;
}
/* Allocate modem channels if necessary */
mask = gsi->modem_channel_bitmap;
while (mask) {
u32 modem_channel_id = __ffs(mask);
ret = gsi_modem_channel_alloc(gsi, modem_channel_id);
if (ret)
goto err_unwind_modem;
/* Clear bit from mask only after success (for unwind) */
mask ^= BIT(modem_channel_id);
}
mutex_unlock(&gsi->mutex);
return 0;
err_unwind_modem:
/* Compute which modem channels need to be deallocated */
mask ^= gsi->modem_channel_bitmap;
while (mask) {
channel_id = __fls(mask);
mask ^= BIT(channel_id);
gsi_modem_channel_halt(gsi, channel_id);
}
err_unwind:
while (channel_id--)
gsi_channel_teardown_one(gsi, channel_id);
mutex_unlock(&gsi->mutex);
gsi_irq_disable(gsi);
return ret;
}
/* Inverse of gsi_channel_setup() */
static void gsi_channel_teardown(struct gsi *gsi)
{
u32 mask = gsi->modem_channel_bitmap;
u32 channel_id;
mutex_lock(&gsi->mutex);
while (mask) {
channel_id = __fls(mask);
mask ^= BIT(channel_id);
gsi_modem_channel_halt(gsi, channel_id);
}
channel_id = gsi->channel_count - 1;
do
gsi_channel_teardown_one(gsi, channel_id);
while (channel_id--);
mutex_unlock(&gsi->mutex);
gsi_irq_disable(gsi);
}
/* Turn off all GSI interrupts initially */
static int gsi_irq_setup(struct gsi *gsi)
{
const struct reg *reg;
int ret;
/* Writing 1 indicates IRQ interrupts; 0 would be MSI */
reg = gsi_reg(gsi, CNTXT_INTSET);
iowrite32(reg_bit(reg, INTYPE), gsi->virt + reg_offset(reg));
/* Disable all interrupt types */
gsi_irq_type_update(gsi, 0);
/* Clear all type-specific interrupt masks */
reg = gsi_reg(gsi, CNTXT_SRC_CH_IRQ_MSK);
iowrite32(0, gsi->virt + reg_offset(reg));
reg = gsi_reg(gsi, CNTXT_SRC_EV_CH_IRQ_MSK);
iowrite32(0, gsi->virt + reg_offset(reg));
reg = gsi_reg(gsi, CNTXT_GLOB_IRQ_EN);
iowrite32(0, gsi->virt + reg_offset(reg));
reg = gsi_reg(gsi, CNTXT_SRC_IEOB_IRQ_MSK);
iowrite32(0, gsi->virt + reg_offset(reg));
/* The inter-EE interrupts are not supported for IPA v3.0-v3.1 */
if (gsi->version > IPA_VERSION_3_1) {
reg = gsi_reg(gsi, INTER_EE_SRC_CH_IRQ_MSK);
iowrite32(0, gsi->virt + reg_offset(reg));
reg = gsi_reg(gsi, INTER_EE_SRC_EV_CH_IRQ_MSK);
iowrite32(0, gsi->virt + reg_offset(reg));
}
reg = gsi_reg(gsi, CNTXT_GSI_IRQ_EN);
iowrite32(0, gsi->virt + reg_offset(reg));
ret = request_irq(gsi->irq, gsi_isr, 0, "gsi", gsi);
if (ret)
dev_err(gsi->dev, "error %d requesting \"gsi\" IRQ\n", ret);
return ret;
}
static void gsi_irq_teardown(struct gsi *gsi)
{
free_irq(gsi->irq, gsi);
}
/* Get # supported channel and event rings; there is no gsi_ring_teardown() */
static int gsi_ring_setup(struct gsi *gsi)
{
struct device *dev = gsi->dev;
const struct reg *reg;
u32 count;
u32 val;
if (gsi->version < IPA_VERSION_3_5_1) {
/* No HW_PARAM_2 register prior to IPA v3.5.1, assume the max */
gsi->channel_count = GSI_CHANNEL_COUNT_MAX;
gsi->evt_ring_count = GSI_EVT_RING_COUNT_MAX;
return 0;
}
reg = gsi_reg(gsi, HW_PARAM_2);
val = ioread32(gsi->virt + reg_offset(reg));
count = reg_decode(reg, NUM_CH_PER_EE, val);
if (!count) {
dev_err(dev, "GSI reports zero channels supported\n");
return -EINVAL;
}
if (count > GSI_CHANNEL_COUNT_MAX) {
dev_warn(dev, "limiting to %u channels; hardware supports %u\n",
GSI_CHANNEL_COUNT_MAX, count);
count = GSI_CHANNEL_COUNT_MAX;
}
gsi->channel_count = count;
if (gsi->version < IPA_VERSION_5_0) {
count = reg_decode(reg, NUM_EV_PER_EE, val);
} else {
reg = gsi_reg(gsi, HW_PARAM_4);
count = reg_decode(reg, EV_PER_EE, val);
}
if (!count) {
dev_err(dev, "GSI reports zero event rings supported\n");
return -EINVAL;
}
if (count > GSI_EVT_RING_COUNT_MAX) {
dev_warn(dev,
"limiting to %u event rings; hardware supports %u\n",
GSI_EVT_RING_COUNT_MAX, count);
count = GSI_EVT_RING_COUNT_MAX;
}
gsi->evt_ring_count = count;
return 0;
}
/* Setup function for GSI. GSI firmware must be loaded and initialized */
int gsi_setup(struct gsi *gsi)
{
const struct reg *reg;
u32 val;
int ret;
/* Here is where we first touch the GSI hardware */
reg = gsi_reg(gsi, GSI_STATUS);
val = ioread32(gsi->virt + reg_offset(reg));
if (!(val & reg_bit(reg, ENABLED))) {
dev_err(gsi->dev, "GSI has not been enabled\n");
return -EIO;
}
ret = gsi_irq_setup(gsi);
if (ret)
return ret;
ret = gsi_ring_setup(gsi); /* No matching teardown required */
if (ret)
goto err_irq_teardown;
/* Initialize the error log */
reg = gsi_reg(gsi, ERROR_LOG);
iowrite32(0, gsi->virt + reg_offset(reg));
ret = gsi_channel_setup(gsi);
if (ret)
goto err_irq_teardown;
return 0;
err_irq_teardown:
gsi_irq_teardown(gsi);
return ret;
}
/* Inverse of gsi_setup() */
void gsi_teardown(struct gsi *gsi)
{
gsi_channel_teardown(gsi);
gsi_irq_teardown(gsi);
}
/* Initialize a channel's event ring */
static int gsi_channel_evt_ring_init(struct gsi_channel *channel)
{
struct gsi *gsi = channel->gsi;
struct gsi_evt_ring *evt_ring;
int ret;
ret = gsi_evt_ring_id_alloc(gsi);
if (ret < 0)
return ret;
channel->evt_ring_id = ret;
evt_ring = &gsi->evt_ring[channel->evt_ring_id];
evt_ring->channel = channel;
ret = gsi_ring_alloc(gsi, &evt_ring->ring, channel->event_count);
if (!ret)
return 0; /* Success! */
dev_err(gsi->dev, "error %d allocating channel %u event ring\n",
ret, gsi_channel_id(channel));
gsi_evt_ring_id_free(gsi, channel->evt_ring_id);
return ret;
}
/* Inverse of gsi_channel_evt_ring_init() */
static void gsi_channel_evt_ring_exit(struct gsi_channel *channel)
{
u32 evt_ring_id = channel->evt_ring_id;
struct gsi *gsi = channel->gsi;
struct gsi_evt_ring *evt_ring;
evt_ring = &gsi->evt_ring[evt_ring_id];
gsi_ring_free(gsi, &evt_ring->ring);
gsi_evt_ring_id_free(gsi, evt_ring_id);
}
static bool gsi_channel_data_valid(struct gsi *gsi, bool command,
const struct ipa_gsi_endpoint_data *data)
{
const struct gsi_channel_data *channel_data;
u32 channel_id = data->channel_id;
struct device *dev = gsi->dev;
/* Make sure channel ids are in the range driver supports */
if (channel_id >= GSI_CHANNEL_COUNT_MAX) {
dev_err(dev, "bad channel id %u; must be less than %u\n",
channel_id, GSI_CHANNEL_COUNT_MAX);
return false;
}
if (data->ee_id != GSI_EE_AP && data->ee_id != GSI_EE_MODEM) {
dev_err(dev, "bad EE id %u; not AP or modem\n", data->ee_id);
return false;
}
if (command && !data->toward_ipa) {
dev_err(dev, "command channel %u is not TX\n", channel_id);
return false;
}
channel_data = &data->channel;
if (!channel_data->tlv_count ||
channel_data->tlv_count > GSI_TLV_MAX) {
dev_err(dev, "channel %u bad tlv_count %u; must be 1..%u\n",
channel_id, channel_data->tlv_count, GSI_TLV_MAX);
return false;
}
if (command && IPA_COMMAND_TRANS_TRE_MAX > channel_data->tlv_count) {
dev_err(dev, "command TRE max too big for channel %u (%u > %u)\n",
channel_id, IPA_COMMAND_TRANS_TRE_MAX,
channel_data->tlv_count);
return false;
}
/* We have to allow at least one maximally-sized transaction to
* be outstanding (which would use tlv_count TREs). Given how
* gsi_channel_tre_max() is computed, tre_count has to be almost
* twice the TLV FIFO size to satisfy this requirement.
*/
if (channel_data->tre_count < 2 * channel_data->tlv_count - 1) {
dev_err(dev, "channel %u TLV count %u exceeds TRE count %u\n",
channel_id, channel_data->tlv_count,
channel_data->tre_count);
return false;
}
if (!is_power_of_2(channel_data->tre_count)) {
dev_err(dev, "channel %u bad tre_count %u; not power of 2\n",
channel_id, channel_data->tre_count);
return false;
}
if (!is_power_of_2(channel_data->event_count)) {
dev_err(dev, "channel %u bad event_count %u; not power of 2\n",
channel_id, channel_data->event_count);
return false;
}
return true;
}
/* Init function for a single channel */
static int gsi_channel_init_one(struct gsi *gsi,
const struct ipa_gsi_endpoint_data *data,
bool command)
{
struct gsi_channel *channel;
u32 tre_count;
int ret;
if (!gsi_channel_data_valid(gsi, command, data))
return -EINVAL;
/* Worst case we need an event for every outstanding TRE */
if (data->channel.tre_count > data->channel.event_count) {
tre_count = data->channel.event_count;
dev_warn(gsi->dev, "channel %u limited to %u TREs\n",
data->channel_id, tre_count);
} else {
tre_count = data->channel.tre_count;
}
channel = &gsi->channel[data->channel_id];
memset(channel, 0, sizeof(*channel));
channel->gsi = gsi;
channel->toward_ipa = data->toward_ipa;
channel->command = command;
channel->trans_tre_max = data->channel.tlv_count;
channel->tre_count = tre_count;
channel->event_count = data->channel.event_count;
ret = gsi_channel_evt_ring_init(channel);
if (ret)
goto err_clear_gsi;
ret = gsi_ring_alloc(gsi, &channel->tre_ring, data->channel.tre_count);
if (ret) {
dev_err(gsi->dev, "error %d allocating channel %u ring\n",
ret, data->channel_id);
goto err_channel_evt_ring_exit;
}
ret = gsi_channel_trans_init(gsi, data->channel_id);
if (ret)
goto err_ring_free;
if (command) {
u32 tre_max = gsi_channel_tre_max(gsi, data->channel_id);
ret = ipa_cmd_pool_init(channel, tre_max);
}
if (!ret)
return 0; /* Success! */
gsi_channel_trans_exit(channel);
err_ring_free:
gsi_ring_free(gsi, &channel->tre_ring);
err_channel_evt_ring_exit:
gsi_channel_evt_ring_exit(channel);
err_clear_gsi:
channel->gsi = NULL; /* Mark it not (fully) initialized */
return ret;
}
/* Inverse of gsi_channel_init_one() */
static void gsi_channel_exit_one(struct gsi_channel *channel)
{
if (!gsi_channel_initialized(channel))
return;
if (channel->command)
ipa_cmd_pool_exit(channel);
gsi_channel_trans_exit(channel);
gsi_ring_free(channel->gsi, &channel->tre_ring);
gsi_channel_evt_ring_exit(channel);
}
/* Init function for channels */
static int gsi_channel_init(struct gsi *gsi, u32 count,
const struct ipa_gsi_endpoint_data *data)
{
bool modem_alloc;
int ret = 0;
u32 i;
/* IPA v4.2 requires the AP to allocate channels for the modem */
modem_alloc = gsi->version == IPA_VERSION_4_2;
gsi->event_bitmap = gsi_event_bitmap_init(GSI_EVT_RING_COUNT_MAX);
gsi->ieob_enabled_bitmap = 0;
/* The endpoint data array is indexed by endpoint name */
for (i = 0; i < count; i++) {
bool command = i == IPA_ENDPOINT_AP_COMMAND_TX;
if (ipa_gsi_endpoint_data_empty(&data[i]))
continue; /* Skip over empty slots */
/* Mark modem channels to be allocated (hardware workaround) */
if (data[i].ee_id == GSI_EE_MODEM) {
if (modem_alloc)
gsi->modem_channel_bitmap |=
BIT(data[i].channel_id);
continue;
}
ret = gsi_channel_init_one(gsi, &data[i], command);
if (ret)
goto err_unwind;
}
return ret;
err_unwind:
while (i--) {
if (ipa_gsi_endpoint_data_empty(&data[i]))
continue;
if (modem_alloc && data[i].ee_id == GSI_EE_MODEM) {
gsi->modem_channel_bitmap &= ~BIT(data[i].channel_id);
continue;
}
gsi_channel_exit_one(&gsi->channel[data->channel_id]);
}
return ret;
}
/* Inverse of gsi_channel_init() */
static void gsi_channel_exit(struct gsi *gsi)
{
u32 channel_id = GSI_CHANNEL_COUNT_MAX - 1;
do
gsi_channel_exit_one(&gsi->channel[channel_id]);
while (channel_id--);
gsi->modem_channel_bitmap = 0;
}
/* Init function for GSI. GSI hardware does not need to be "ready" */
int gsi_init(struct gsi *gsi, struct platform_device *pdev,
enum ipa_version version, u32 count,
const struct ipa_gsi_endpoint_data *data)
{
int ret;
gsi_validate_build();
gsi->dev = &pdev->dev;
gsi->version = version;
/* GSI uses NAPI on all channels. Create a dummy network device
* for the channel NAPI contexts to be associated with.
*/
init_dummy_netdev(&gsi->dummy_dev);
init_completion(&gsi->completion);
ret = gsi_reg_init(gsi, pdev);
if (ret)
return ret;
ret = gsi_irq_init(gsi, pdev); /* No matching exit required */
if (ret)
goto err_reg_exit;
ret = gsi_channel_init(gsi, count, data);
if (ret)
goto err_reg_exit;
mutex_init(&gsi->mutex);
return 0;
err_reg_exit:
gsi_reg_exit(gsi);
return ret;
}
/* Inverse of gsi_init() */
void gsi_exit(struct gsi *gsi)
{
mutex_destroy(&gsi->mutex);
gsi_channel_exit(gsi);
gsi_reg_exit(gsi);
}
/* The maximum number of outstanding TREs on a channel. This limits
* a channel's maximum number of transactions outstanding (worst case
* is one TRE per transaction).
*
* The absolute limit is the number of TREs in the channel's TRE ring,
* and in theory we should be able use all of them. But in practice,
* doing that led to the hardware reporting exhaustion of event ring
* slots for writing completion information. So the hardware limit
* would be (tre_count - 1).
*
* We reduce it a bit further though. Transaction resource pools are
* sized to be a little larger than this maximum, to allow resource
* allocations to always be contiguous. The number of entries in a
* TRE ring buffer is a power of 2, and the extra resources in a pool
* tends to nearly double the memory allocated for it. Reducing the
* maximum number of outstanding TREs allows the number of entries in
* a pool to avoid crossing that power-of-2 boundary, and this can
* substantially reduce pool memory requirements. The number we
* reduce it by matches the number added in gsi_trans_pool_init().
*/
u32 gsi_channel_tre_max(struct gsi *gsi, u32 channel_id)
{
struct gsi_channel *channel = &gsi->channel[channel_id];
/* Hardware limit is channel->tre_count - 1 */
return channel->tre_count - (channel->trans_tre_max - 1);
}